A touch input device capable of detecting a pressure of a touch on a touch surface may be provided that includes: a display module; and a pressure sensor which is disposed at a position where a distance between the pressure sensor and a reference potential layer is changeable according to the touch on the touch surface. The distance is changeable according to a pressure magnitude of the touch. The pressure sensor outputs a signal including information on a capacitance which is changed according to the distance. The pressure sensor includes a plurality of electrodes to form a plurality of channels. The pressure magnitude of the touch is detected on the basis of a change amount of the capacitance detected in each of the channels. According to the embodiment of the present invention, it is possible to provide a pressure sensor for pressure detection, a touch input device including the same, and a pressure detection method using the same. In addition, according to the embodiment of the present invention, it is possible to provide the pressure sensor having a high-pressure detection accuracy of the touch and the touch input device including the pressure sensor.
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15. A touch input device capable of detecting a pressure of a touch on a touch surface, the touch input device comprising:
a display module; and
a pressure sensor which is disposed at a position where a distance between the pressure sensor and a reference potential layer is changeable according to the touch on the touch surface,
wherein the distance is changeable according to a pressure magnitude of the touch,
wherein the pressure sensor outputs a signal comprising information on a capacitance which is changed according to the distance,
wherein the pressure sensor comprises an electrode forming a single channel,
wherein a volume change amount of the touch input device is estimated from a change amount of the capacitance detected in the single channel,
and wherein the pressure magnitude of the touch is detected on the basis of the estimated volume change amount.
1. A touch input device capable of detecting a pressure of a touch on a touch surface, the touch input device comprising:
a display module; and
a pressure sensor which is disposed at a position where a distance between the pressure sensor and a reference potential layer is changeable according to the touch on the touch surface,
wherein the distance is changeable according to a pressure magnitude of the touch,
wherein the pressure sensor outputs a signal comprising information on a capacitance which is changed according to the distance,
wherein the pressure sensor comprises a plurality of electrodes to form a plurality of channels,
wherein the pressure magnitude of the touch is detected on the basis of a change amount of the capacitance detected in each of the channels; and
wherein the pressure magnitude of the touch is detected based on a sum of values obtained by multiplying the change amount of the capacitance detected in each of the channels by a scaling factor assigned previously to each of the channels.
12. A touch input device capable of detecting a pressure of a touch on a touch surface, the touch input device comprising:
a display module; and
a pressure sensor which is disposed at a position where a distance between the pressure sensor and a reference potential layer is changeable according to the touch on the touch surface,
wherein the distance is changeable according to a pressure magnitude of the touch,
wherein the pressure sensor outputs a signal comprising information on a capacitance which is changed according to the distance,
wherein the pressure sensor comprises a plurality of electrodes to form a plurality of channels,
wherein the pressure magnitude of the touch is detected on the basis of a change amount of the capacitance detected in each of the channels; and
wherein a volume change amount of the touch input device is estimated based on the change amount of the capacitance detected in each of the channels,
and wherein the pressure magnitude of the touch is detected based on the estimated volume change amount.
2. The touch input device of
3. The touch input device of
4. The touch input device of
5. The touch input device of
6. The touch input device
7. The touch input device of
wherein the electrode comprises a first electrode and a second electrode,
and wherein the capacitance is a capacitance between the first electrode and the second electrode.
8. The touch input device of
wherein the display module comprises:
a display panel; and
a backlight unit which is disposed under the display panel and comprises a reflective sheet and a cover,
and wherein the pressure sensor is attached to the cover, between the reflective sheet and the cover.
9. The touch input device of
10. The touch input device of
11. The touch input device of
13. The touch input device of
14. The touch input device of
16. The touch input device of
17. The touch input device of
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The present application is a U.S. national stage application under 35 U.S.C. § 371 of PCT Application No. PCT/IB2016/051916, filed Apr. 5, 2016, the disclosure of which is incorporated by reference in its entirety.
The present disclosure relates to a pressure sensor for pressure detection and a touch input device including the same, and more particularly to a pressure sensor which is applied to a touch input device configured to detect a touch position and is capable of detecting a touch pressure, the touch input device including the same, and a pressure detection method using the same.
Various kinds of input devices are being used to operate a computing system. For example, the input device includes a button, key, joystick and touch screen. Since the touch screen is easy and simple to operate, the touch screen is increasingly being used to operate the computing system.
The touch screen may constitute a touch surface of a touch input device including a touch sensor panel which may be a transparent panel including a touch-sensitive surface. The touch sensor panel is attached to the front side of a display screen, and then the touch-sensitive surface may cover the visible side of the display screen. The touch screen allows a user to operate the computing system by simply touching the touch screen by a finger, etc. Generally, the computing system recognizes the touch and a position of the touch on the touch screen and analyzes the touch, and thus, performs operations in accordance with the analysis.
Here, there is a demand for a touch input device capable of detecting not only the touch position according to the touch on the touch screen but a pressure magnitude of the touch.
The object of the present invention is to provide a pressure sensor for pressure detection, a touch input device including the same, and a pressure detection method using the same.
One embodiment is a touch input device capable of detecting a pressure of a touch on a touch surface. The touch input device includes: a display module; and a pressure sensor which is disposed at a position where a distance between the pressure sensor and a reference potential layer is changeable according to the touch on the touch surface. The distance is changeable according to a pressure magnitude of the touch. The pressure sensor outputs a signal including information on a capacitance which is changed according to the distance. The pressure sensor includes a plurality of electrodes to form a plurality of channels. The pressure magnitude of the touch is detected on the basis of a change amount of the capacitance detected in each of the channels. According to the embodiment of the present invention, it is possible to provide a pressure sensor for pressure detection, a touch input device including the same, and a pressure detection method using the same. In addition, according to the embodiment of the present invention, it is possible to provide the pressure sensor having a high-pressure detection accuracy of the touch and the touch input device including the pressure sensor.
Another embodiment is a pressure sensor including a first insulation layer and a second insulation layer and a first electrode and a second electrode which are located between the first insulation layer and the second insulation layer. A capacitance between the first electrode and the second electrode, which is changed according to a relative distance change between the pressure sensor and a reference potential layer spaced apart the pressure sensor is detected. The pressure sensor is configured such that a magnitude of a pressure which causes the distance change through the capacitance is detected. The pressure sensor is configured to include a plurality of the first electrodes and a plurality of the second electrodes and to form a plurality of channels. The pressure sensor is used to detect the pressure magnitude of a touch on the basis of a change amount of the capacitance detected in each of the channels.
Further another embodiment is a pressure sensor including a first insulation layer and a second insulation layer and an electrode located between the first insulation layer and the second insulation layer. A capacitance between the electrode and a reference potential layer, which is changed according to a relative distance change between the pressure sensor and the reference potential layer spaced apart the pressure sensor is detected. The pressure sensor is configured such that a magnitude of a pressure which causes the distance change through the capacitance is detected. The pressure sensor is configured to include a plurality of the electrodes and to form a plurality of channels. The pressure sensor is used to detect the pressure magnitude of a touch on the basis of a change amount of the capacitance detected in each of the channels.
According to the embodiment of the present invention, it is possible to provide a pressure sensor for pressure detection, a touch input device including the same, and a pressure detection method using the same.
In addition, according to the embodiment of the present invention, it is possible to provide the pressure sensor having a high-pressure detection accuracy of the touch and the touch input device including the pressure sensor.
Cross sections of the pressure sensor according to the embodiment of the present invention are shown in (a) to (d) of
The following detailed description of the present invention shows a specified embodiment of the present invention and will be provided with reference to the accompanying drawings. The embodiment will be described in enough detail that those skilled in the art are able to embody the present invention. It should be understood that various embodiments of the present invention are different from each other and need not be mutually exclusive. Similar reference numerals in the drawings designate the same or similar functions in many aspects.
Hereinafter, a pressure sensor for pressure detection and a touch input device to which a pressure detection module including the pressure sensor according to an embodiment of the present invention can be applied will be described with reference to the accompanying drawings. Hereinafter, while a capacitance type touch sensor panel 100 is exemplified below, the touch sensor panel 100 capable of detecting a touch position in any manner may be applied.
As shown in
As shown in
In the touch sensor panel 100 according to the embodiment of the present invention, the plurality of drive electrodes TX1 to TXn and the plurality of receiving electrodes RX1 to RXm may be formed in the same layer. For example, the plurality of drive electrodes TX1 to TXn and the plurality of receiving electrodes RX1 to RXm may be formed on the same side of an insulation layer (not shown). Also, the plurality of drive electrodes TX1 to TXn and the plurality of receiving electrodes RX1 to RXm may be formed in the different layers. For example, the plurality of drive electrodes TX1 to TXn and the plurality of receiving electrodes RX1 to RXm may be formed on both sides of one insulation layer (not shown) respectively, or the plurality of drive electrodes TX1 to TXn may be formed on a side of a first insulation layer (not shown) and the plurality of receiving electrodes RX1 to RXm may be formed on a side of a second insulation layer (not shown) different from the first insulation layer.
The plurality of drive electrodes TX1 to TXn and the plurality of receiving electrodes RX1 to RXm may be made of a transparent conductive material (for example, indium tin oxide (ITO) or antimony tin oxide (ATO) which is made of tin oxide (SnO2), and indium oxide (In2O3), etc.), or the like. However, this is only an example. The drive electrode TX and the receiving electrode RX may be also made of another transparent conductive material or an opaque conductive material. For instance, the drive electrode TX and the receiving electrode RX may be formed to include at least any one of silver ink, copper or carbon nanotube (CNT). Also, the drive electrode TX and the receiving electrode RX may be made of metal mesh or nano silver.
The drive unit 120 according to the embodiment of the present invention may apply a driving signal to the drive electrodes TX1 to TXn. In the embodiment of the present invention, one driving signal may be sequentially applied at a time to the first drive electrode TX1 to the n-th drive electrode TXn. The driving signal may be applied again repeatedly. This is only an example. The driving signal may be applied to the plurality of drive electrodes at the same time in accordance with the embodiment.
Through the receiving electrodes RX1 to RXm, the sensing unit 110 receives the sensing signal including information on a capacitance (Cm) 101 generated between the receiving electrodes RX1 to RXm and the drive electrodes TX1 to TXn to which the driving signal has been applied, thereby detecting whether or not the touch has occurred and where the touch has occurred. For example, the sensing signal may be a signal coupled by the capacitance (CM) 101 generated between the receiving electrode RX and the drive electrode TX to which the driving signal has been applied. As such, the process of sensing the driving signal applied from the first drive electrode TX1 to the n-th drive electrode TXn through the receiving electrodes RX1 to RXm can be referred to as a process of scanning the touch sensor panel 100.
For example, the sensing unit 110 may include a receiver (not shown) which is connected to each of the receiving electrodes RX1 to RXm through a switch. The switch becomes the on-state in a time interval during which the signal of the corresponding receiving electrode RX is sensed, thereby allowing the receiver to sense the sensing signal from the receiving electrode RX. The receiver may include an amplifier (not shown) and a feedback capacitor coupled between the negative (−) input terminal of the amplifier and the output terminal of the amplifier, i.e., coupled to a feedback path. Here, the positive (+) input terminal of the amplifier may be connected to the ground or a reference voltage. Also, the receiver may further include a reset switch which is connected in parallel with the feedback capacitor. The reset switch may reset the conversion from current to voltage that is performed by the receiver. The negative input terminal of the amplifier is connected to the corresponding receiving electrode RX and receives and integrates a current signal including information on the capacitance (CM) 101, and then converts the integrated current signal into voltage. The sensing unit 110 may further include an analog-digital converter (ADC) (not shown) which converts the integrated data by the receiver into digital data. Later, the digital data may be input to a processor (not shown) and processed to obtain information on the touch on the touch sensor panel 100. The sensing unit 110 may include the ADC and processor as well as the receiver.
A controller 130 may perform a function of controlling the operations of the drive unit 120 and the sensing unit 110. For example, the controller 130 generates and transmits a drive control signal to the drive unit 120, so that the driving signal can be applied to a predetermined drive electrode TX1 at a predetermined time. Also, the controller 130 generates and transmits the drive control signal to the sensing unit 110, so that the sensing unit 110 may receive the sensing signal from the predetermined receiving electrode RX at a predetermined time and perform a predetermined function.
In
As described above, a capacitance (C) with a predetermined value is generated at each crossing of the drive electrode TX and the receiving electrode RX. When an object like a finger approaches close to the touch sensor panel 100, the value of the capacitance may be changed. In
More specifically, when the touch occurs on the touch sensor panel 100, the drive electrode TX to which the driving signal has been applied is detected, so that the position of the second axial direction of the touch can be detected. Likewise, when the touch occurs on the touch sensor panel 100, the capacitance change is detected from the reception signal received through the receiving electrode RX, so that the position of the first axial direction of the touch can be detected.
The mutual capacitance type touch sensor panel as the touch sensor panel 100 has been described in detail in the foregoing. However, in the touch input device 1000 according to the embodiment of the present invention, the touch sensor panel 100 for detecting whether or not the touch has occurred and where the touch has occurred may be implemented by using not only the above-described method but also any touch sensing method like a self-capacitance type method, a surface capacitance type method, a projected capacitance type method, a resistance film method, a surface acoustic wave (SAW) method, an infrared method, an optical imaging method, a dispersive signal technology, and an acoustic pulse recognition method, etc.
Hereinafter, a component corresponding to the drive electrode TX and the receiving electrode RX for detecting whether or not the touch has occurred and/or the touch position can be referred to as a touch sensor.
In the pressure sensor and the touch input device 1000 to which the pressure detection module including the pressure sensor can be applied according to the embodiment of the present invention, the touch sensor panel 100 may be positioned outside or inside a display panel 200A. The display panel 200A of the touch input device 1000 according to the embodiment of the present invention may be a display panel included in a liquid crystal display (LCD), a plasma display panel (PDP), an organic light emitting diode (OLED), etc. Accordingly, a user may perform the input operation by touching the touch surface while visually identifying an image displayed on the display panel. Here, the display panel 200A may include a control circuit which receives an input from an application processor (AP) or a central processing unit (CPU) on a main board for the operation of the touch input device 1000 and displays the contents that the user wants on the display panel. Here, the control circuit for the operation of the display panel 200A may be mounted on a second printed circuit board (hereafter, referred to as a second PCB) (210) in
As shown in
It is clear to those skilled in the art that the LCD panel may further include other configurations for the purpose of performing the displaying function and may be transformed.
Next, a relative position of the touch sensor panel 100 with respect to the display panel 200A using an OLED panel will be described with reference to
Here, the first substrate 281 may be made of encapsulation glass. The second substrate 283 may be made of TFT glass. Also, the first substrate 281 and/or the second substrate 283 may be plastic substrates. Since the touch sensing has been described above, the other configurations only will be briefly described.
The OLED panel is a self-light emitting display panel which uses a principle where, when current flows through a fluorescent or phosphorescent organic thin film and then electrons and electron holes are combined in the organic material layer, so that light is generated. The organic matter constituting the light emitting layer determines the color of the light.
Specifically, the OLED uses a principle in which when electricity flows and an organic matter is applied on glass or plastic, the organic matter emits light. That is, the principle is that electron holes and electrons are injected into the anode and cathode of the organic matter respectively and are recombined in the light emitting layer, so that a high energy exciton is generated and the exciton releases the energy while falling down to a low energy state and then light with a particular wavelength is generated. Here, the color of the light is changed according to the organic matter of the light emitting layer.
The OLED includes a line-driven passive-matrix organic light-emitting diode (PM-OLED) and an individual driven active-matrix organic light-emitting diode (AM-OLED) in accordance with the operating characteristics of a pixel constituting a pixel matrix. None of them require a backlight. Therefore, the OLED enables a very thin display module to be implemented, has a constant contrast ratio according to an angle and obtains a good color reproductivity depending on a temperature. Also, it is very economical in that non-driven pixel does not consume power.
In terms of operation, the PM-OLED emits light only during a scanning time at a high current, and the AM-OLED maintains a light emitting state only during a frame time at a low current. Therefore, the AM-OLED has a resolution higher than that of the PM-OLED and is advantageous for driving a large area display panel and consumes low power. Also, a thin film transistor (TFT) is embedded in the AM-OLED, and thus, each component can be individually controlled, so that it is easy to implement a delicate screen.
As shown in
Also, the organic layer 280 may include a hole injection layer (HIL), a hole transport layer (HTL), an electron injection layer (EIL), an electron transport layer (ETL), and an emission material layer (EML).
Briefly describing each of the layers, HIL injects electron holes and is made of a material such as CuPc, etc. HTL functions to move the injected electron holes and mainly is made of a material having a good hole mobility. Arylamine, TPD, and the like may be used as the HTL. The EIL and ETL inject and transport electrons. The injected electrons and electron holes are combined in the EML and emit light. The EML represents the color of the emitted light and is composed of a host determining the lifespan of the organic matter and an impurity (dopant) determining the color sense and efficiency. This just describes the basic structure of the organic layer 280 include in the OLED panel. The present invention is not limited to the layer structure or material, etc., of the organic layer 280.
The organic layer 280 is inserted between an anode (not shown) and a cathode (not shown). When the TFT becomes an on-state, a driving current is applied to the anode and the electron holes are injected, and the electrons are injected to the cathode. Then, the electron holes and electrons move to the organic layer 280 and emit the light.
Also, according to the embodiment, at least a portion of the touch sensor may be disposed within the display panel 200A and at least the remaining portion of the touch sensor may be disposed outside the display panel 200A. For example, any one of the drive electrode TX and the receiving electrode RX which constitute the touch sensor panel 100 may be disposed outside the display panel 200A and the other may be disposed within the display panel 200A. When the touch sensor is disposed within the display panel 200A, an electrode for the operation of the touch sensor may be further added. In addition, various components and/or electrodes disposed within the display panel 200A can be also used as the touch sensor for touch sensing.
Also, according to the embodiment, at least a portion of the touch sensor may be disposed between the first substrate 261 and 281 and the second substrate 262 and 283 and at least the remaining portion of the touch sensor may be disposed on the first substrate 261 and 281. For example, any one of the drive electrode TX and the receiving electrode RX which constitute the touch sensor panel 100 may be disposed on the first substrate 261 and 281 and the other may be disposed between the first substrate 261 and 281 and the second substrate 262 and 283. Here, likewise, when the touch sensor is disposed between the first substrate 261 and 281 and the second substrate 262 and 283, an electrode for the operation of the touch sensor may be further added. In addition, various components and/or electrodes disposed between the first substrate 261 and 281 and the second substrate 262 and 283 can be also used as the touch sensor for touch sensing.
The second substrate 262 and 283 may be comprised of various layers including a data line a gate line, TFT, a common electrode, and a pixel electrode, etc. Specifically, when the display panel 200A is the LCD panel, these electrical components may operate in such a manner as to generate a controlled electric field and orient liquid crystals located in the liquid crystal layer 250. Any one of the data line, the gate line, the common electrode, and the pixel electrode included in the second substrate 262 and 283 may be configured to be used as the touch sensor.
The foregoing has described the touch input device 1000 including the touch sensor panel 100 capable of detecting whether or not the touch has occurred and/or the touch position. The pressure sensor 440 according to the embodiment of the present invention is applied to the aforementioned touch input device 1000, so that it is possible to easily detect a magnitude of a touch pressure as well as whether or not the touch has occurred and/or the touch position. Hereinafter, described in detail is an example of a case of detecting the touch pressure by applying the electrode sheet according to the embodiment of the present invention to the touch input device 1000. According to the embodiment, the touch input device to which the pressure detection module is applied may not have the touch sensor panel 100.
The cross sectional view of the touch input device 1000 shown in
The touch input device 1000 according to the embodiment of the present invention may include an electronic device including the touch screen, for example, a cell phone, a personal data assistant (PDA), a smart phone, a tablet personal computer, an MP3 player, a laptop computer, etc.
At least a portion of the touch sensor is included within the display panel 200A in the touch input device 1000 according to the embodiment. Also, according to the embodiment, the drive electrode and the receiving electrode which are for sensing the touch may be included within the display panel 200A.
The cover layer 500 according to the embodiment may be comprised of a cover glass which protects the front side of the display panel 200A and forms the touch surface. As shown in
Since the display panel 200A such as the LCD panel according to the embodiment performs a function of only blocking or transmitting the light without emitting light by itself, the backlight unit 200B may be required. For example, the backlight unit 200B is disposed under the display panel 200A, includes a light source and throws the light on the display panel 200A, so that not only brightness and darkness but also information having a variety of colors is displayed on the screen. Since the display panel 200A is a passive device, it is not self-luminous. Therefore, the rear side of the display panel 200A requires a light source having a uniform luminance distribution.
The backlight unit 200B according to the embodiment may include an optical layer 220 for illuminating the display panel 200A. The optical layer 220 will be described in detail with reference to
The backlight unit 200B according to the embodiment may include the cover 240. The cover 240 may be made of a metallic material. When a pressure is applied from the outside through the cover layer 500 of the touch input device 1000, the cover layer 500, the display module 200, etc., may be bent. Here, the bending causes a distance between the pressure sensor 450 and 460 and a reference potential layer located within the display module to be changed. The capacitance change caused by the distance change is detected through the pressure sensors 450 and 460, so that the magnitude of the pressure can be detected. Here, a pressure is applied to the cover layer 500 in order to precisely detect the magnitude of the pressure, the position of the pressure sensors 450 and 460 needs to be fixed without changing. Therefore, the cover 240 is able to perform a function of a support capable of fixing a pressure sensor without being relatively bent even by the application of pressure. According to the embodiment, the cover 240 is manufactured separately from the backlight unit 200B, and may be assembled together when the display module is manufactured.
In the touch input device 1000 according to the embodiment, a first air gap 210′ may be included between the display panel 200A and the backlight unit 200B. This intends to protect the display panel 200A and/or the backlight unit 200B from an external impact. This first air gap 210′ may be included in the backlight unit 200B.
The optical layer 220 and the cover 240, which are included in the backlight unit 200B, may be configured to be spaced apart from each other. A second air gap 230 may be provided between the optical layer 220 and the cover 240. The second air gap 230 may be required in order to ensure that the pressure sensors 450 and 460 disposed on the cover 240 does not contact with the optical layer 220, and in order to prevent that the optical layer 220 contacts with the pressure sensors 450 and 460 and deteriorates the performance of the optical layer 220 even though an external pressure is applied to the cover layer 500 and the optical layer 220, the display panel 200A, and the cover layer 500 are bent.
The touch input device 1000 according to the embodiment may further include supports 251 and 252 such that the display panel 200A, the backlight unit 200B, and the cover layer 500 are coupled to maintain a fixed shape. According to the embodiment, the cover 240 may be integrally formed with the support 251 and 252. According to the embodiment, the support 251 and 252 may form a portion of the backlight unit 200B.
The structure and function of the LCD panel 200A and the backlight unit 200B is a publicly known art and will be briefly described below. The backlight unit 200B may include several optical parts.
In
The light guide plate 222 may generally convert lights from the light source (not shown) in the form of a linear light source or point light source into light from a light source in the form of a surface light source, and allow the light to proceed to the LCD panel 200A.
A part of the light emitted from the light guide plate 222 may be emitted to a side opposite to the LCD panel 200A and be lost. The reflective sheet 221 may be positioned below the light guide plate 222 so as to cause the lost light to be incident again on the light guide plate 222, and may be made of a material having a high reflectance.
The diffuser sheet 223 functions to diffuse the light incident from the light guide plate 222. For example, light scattered by the pattern of the light guide plate 222 comes directly into the eyes of the user, and thus, the pattern of the light guide plate 222 may be shown as it is. Moreover, since such a pattern can be clearly sensed even after the LCD panel 200A is mounted, the diffuser sheet 223 is able to perform a function to offset the pattern of the light guide plate 222.
After the light passes through the diffuser sheet 223, the luminance of the light is rapidly reduced. Therefore, the prism sheet 224 may be included in order to improve the luminance of the light by focusing the light again. The prism sheet 224 may include, for example, a horizontal prism sheet and a vertical prism sheet.
The backlight unit 200B according to the embodiment may include a configuration different from the above-described configuration in accordance with the technical change and development and/or the embodiment. The backlight unit 200B may further include an additional configuration as well as the foregoing configuration. Also, in order to protect the optical configuration of the backlight unit 200B from external impacts and contamination, etc., due to the introduction of the alien substance, the backlight unit 200B according to the embodiment may further include, for example, a protection sheet on the prism sheet 224. The backlight unit 200B may also further include a lamp cover in accordance with the embodiment so as to minimize the optical loss of the light source. The backlight unit 200B may also further include a frame which maintains a shape enabling the light guide plate 222, the diffuser sheet 223, the prism sheet 224, a lamp (not shown), and the like, which are main components of the backlight unit 200B, to be exactly combined together in accordance with an allowed dimension. Also, the each of the configurations may be comprised of at least two separate parts.
According to the embodiment, an additional air gap may be positioned between the light guide plate 222 and the reflective sheet 221. As a result, the lost light from the light guide plate 222 to the reflective sheet 221 can be incident again on the light guide plate 222 by the reflective sheet 221. Here, between the light guide plate 222 and the reflective sheet 221, for the purpose of maintaining the additional air gap, the double-sided adhesive tape (DAT) may be included on the edges of the light guide plate 222 and the reflective sheet 221.
As described above, the backlight unit 200B and the display module including the backlight unit 200B may be configured to include in itself the air gap such as the first air gap 210′ and/or the second air gap 230. Also, the air gap may be included between a plurality of the layers included in the optical layer 220. Although the foregoing has described that the LCD panel 200A is used, the air gap may be included within the structure of another display panel.
In the touch input device 1000, the cover layer 500 may be formed wider than the display module 200, the substrate 300, and the mounting space 310. As a result, the second cover 320 is formed in such a manner as to surround the display module 200, the substrate 300, and the mounting space 310 where the circuit board is located. Also, according to the embodiment, the pressure sensor 440 may be included between the display module 200 and the substrate 300.
As with
Here, the pressure sensor 440 may be attached to the substrate 300, may be attached to the display module 200, or may be attached to the display module 200 and the substrate 300.
As shown in
Hereafter, in the touch input device 1000 according to the embodiment of the present invention, the principle and structure for detecting the magnitude of touch pressure by using the pressure sensor 440 will be described in detail. In
In
In the touch input device 1000 according to the embodiment, the spacer layer may be located between the reference potential layer 600 and the pressure sensors 450 and 460. As a result, when a pressure is applied to the cover layer 500, the reference potential layer 600 is bent, so that a relative distance between the reference potential layer 600 and the pressure sensors 450 and 460 may be reduced. The spacer layer may be implemented by the air gap. According to the embodiment, the spacer layer 420 may be made of an impact absorbing material. Here, the impact absorbing material may include sponge and a graphite layer. The spacer layer 420 may be filled with a dielectric material in accordance with the embodiment. The spacer layer 420 may be formed through a combination of the air gap, the impact absorbing material, and the dielectric material.
In the touch input device 1000 according to the embodiment, the display module 200 may be bent or pressed by the touch applying the pressure. The display module may be bent or pressed in such a manner as to show the biggest transformation at the touch position. When the display module is bent or pressed according to the embodiment, a position showing the biggest transformation may not match the touch position. However, the display module may be shown to be bent or pressed at least at the touch position. For example, when the touch position approaches close to the border, edge, etc., of the display module, the most bent or pressed position of the display module may not match the touch position. The border or edge of the display module may not be shown to be bent very little depending on the touch.
Here, since the display module 200 in the touch input device 1000 according to the embodiment of the present invention may be bent or pressed by the application of the pressure, the components (a double-side adhesive tape, an adhesive tape 430, the supports 251 and 252, etc.) which are disposed at the border in order to maintain the air gaps 210 and 310 and/or the spacer layer 420 may be made of an inelastic material. That is, even though the components which are disposed at the border in order to maintain the air gaps 210 and 310 and/or the spacer layer 420 are not compressed or pressed, the touch pressure can be detected by the bending, etc., of the display module 200.
When the cover layer 500, the display panel 200A, and/or the back light unit 200B are bent or pressed at the time of touching the touch input device 1000 according to the embodiment, the cover 240 positioned below the spacer layer, as shown in
According to the embodiment, the spacer layer may be implemented in the form of the air gap. The spacer layer may be made of an impact absorbing material in accordance with the embodiment. The spacer layer may be filled with a dielectric material in accordance with the embodiment.
The reference potential layer 600 may have any potential which causes the change of the mutual capacitance generated between the first electrode 450 and the second electrode 460. For instance, the reference potential layer 600 may be a ground layer having a ground potential. The reference potential layer 600 may be any ground layer which is included in the display module. According to the embodiment, the reference potential layer 600 may be a ground potential layer which is included in itself during the manufacture of the touch input device 1000. For example, in the display panel 200A shown in
When a pressure is applied to the cover layer 500 by means of an object, at least a portion of the display panel 200A and/or the backlight unit 200B is bent, so that a relative distance between the reference potential layer 600 and the first and second electrodes 450 and 460 may be reduced from “d” to “d′”. Here, the less the distance between the reference potential layer 600 and the first and second electrodes 450 and 460 is, the less the value of the mutual capacitance between the first electrode 450 and the second electrode 460 may be. This is because the distance between the reference potential layer 600 and the first and second electrodes 450 and 460 is reduced from “d” to “d′”, so that a fringing capacitance of the mutual capacitance is absorbed in the reference potential layer 600 as well as in the object. When a nonconductive object touches, the change of the mutual capacitance is simply caused by only the change of the distance “d-d′” between the reference potential layer 600 and the electrodes 450 and 460.
The foregoing has described that the pressure sensor 440 includes the first electrode 450 and the second electrode 460 and the pressure is detected by the change of the mutual capacitance between the first electrode 450 and the second electrode 460. The pressure sensor 440 may be configured to include only any one of the first electrode 450 and the second electrode 460 (for example, the first electrode 450).
For example, the magnitude of the touch pressure can be detected by the change of the capacitance between the first electrode 450 and the reference potential layer 600, which is caused by the distance change between the reference potential layer 600 and the first electrode 450. Since the distance “d” is reduced with the increase of the touch pressure, the capacitance between the reference potential layer 600 and the first electrode 450 may be increased with the increase of the touch pressure.
Although the foregoing has described that the pressure sensor 440 is attached to the cover 240 by referencing the touch input device 1000 shown in
The foregoing has described that the reference potential layer 600 is located apart from the components to which the pressure sensor 440 is attached in the touch input device 1000. It will be described in
As shown in
As shown in
When the magnitude of the touch pressure is detected as the mutual capacitance between the first electrode 450 and the second electrode 460 is changed, it is necessary to form the patterns of the first electrode 450 and the second electrode 460 so as to generate the range of the capacitance required to improve the detection accuracy. With the increase of a facing area or facing length of the first electrode 450 and the second electrode 460, the size of the capacitance that is generated may become larger. Therefore, the pattern can be designed by adjusting the size of the facing area, facing length and facing shape of the first electrode 450 and the second electrode 460 in accordance with the range of the necessary capacitance.
The electrode pattern shown in
The electrode pattern shown in
The touch pressure with a sufficient magnitude makes a state where the distance between the pressure sensor 440 and the substrate 300 cannot be reduced any more at a predetermined position. Hereafter, the state is designated as a saturation state. For instance, as shown in
However, in this case, when the magnitude of the touch pressure becomes larger, the contact area between the pressure sensor 440 and the substrate 300 in the saturation state where the distance between the pressure sensor 440 and the substrate 300 cannot be reduced any more may become greater. For example, as shown in
The top surface of the substrate 300 may also have the ground potential in order to block the noise.
Cross sections of a portion of the pressure sensor attached to the touch input device in accordance with the embodiment of the present invention are shown in (a) to (d) of
For example, when the first electrode 450 and the second electrode 460 included in the pressures sensor 440 are formed in the same layer, the pressure sensor 440 may be configured as shown in (a) of
In the pressure sensor 440, it can be considered that the first electrode 450 and the second electrode 460 are formed in different layers in accordance with the embodiment and form the electrode layer. A cross section when the first electrode 450 and the second electrode 460 are formed in different layers is shown in (b) of
A cross section when the pressure sensor 440 is formed to include only the first electrode 450 is shown in (c) of
A cross section when the first pressure sensor 440-1 including the first electrode 450 is attached to the substrate 300 and the second pressure sensor 440-2 including the second electrode 460 is attached to the display module 200 is shown in (d) of
As with the description related to (a) of
The foregoing has described the case where the touch pressure is applied to the top surface of the touch input device 1000. However, even when the touch pressure is applied to the bottom surface of the touch input device 1000, the pressure sensor 440 is able to detect the touch pressure in the same manner.
As shown in
When the pressure electrodes 450 and 460 included in the pressure sensor 440 are made of soft conductive metal such as Al, Ag, and Cu, the pressure electrodes 450 and 460 have a low rigidity and a thickness of only several micrometers. Therefore, the original shape of the pressure sensor 440 is difficult to maintain only by the pressure electrodes 450 and 460. Accordingly, it is recommended that the first insulation layer 470 or the second insulation layer 471 which is disposed on or under the pressure electrodes 450 and 460 has a rigidity enough to maintain the original shape of the pressure sensor 440.
Specifically, as shown in
Here, when the reference potential layer 600 which is disposed apart from the pressure sensor 440 does not have a uniform reference potential according to each input position, or when the distance change between the reference potential layer and the electrode layer is not uniform for the pressure having the same magnitude in accordance with the input position, for example, when the surface of the reference potential layer 600 which is disposed apart from the pressure sensor 440 is not uniform, it may be difficult to use the capacitance change amount between the electrode layer and the reference potential layer 600 which is disposed apart from the pressure sensor 440. As shown in
The support layers 470b and 471b may be made of a material, for example, a resin material, highly rigid metal, paper, or the like, which has a rigidity capable of maintaining the shape of the pressure sensor 440 even when the distance change occurs between the pressure sensor 440 and the reference potential layer 600.
The pressure sensor 440 may further include the first insulation layer 470 and the second insulation layer 471. Here, the electrode layer may be located between the first insulation layer 470 and the second insulation layer 471, and the support layers 470b and 471b may be included in at least any one of the first insulation layer 470 and the second insulation layer 472.
The first insulation layer 470 or the second insulation layer 471 may further include electrode covering layers 470a and 471a. The electrode covering layers 470a and 471a may function to insulate the electrode layer and may function to protect the electrode layer, for example, to prevent the electrode from being oxidized, scraped, cracked, or the like. Also, the electrode covering layers 470a and 471a are formed of or coated with a material with a color, thereby preventing the pressure sensor 440 from being degraded due to exposure to the sun during the distribution of the pressure sensor 440. Here, the electrode covering layers 470a and 471a may be adhered to the electrode layer or to the support layers 470b and 471b by means of an adhesive or may be printed or coated on the support layers 470b and 471b. The electrode covering layers 470a and 471a may be also made of a highly rigid resin material. However, since the thickness of the electrode covering layer is only several micrometers, it is difficult to maintain the original shape of the pressure sensor 440 of about 100 μm.
Also, as shown in
As shown in
As shown in
Preferably, only one of the first and second insulation layers 470 and 471 may include the support layers 470b and 471b. Specifically, in the state where the pressure sensor 440 is attached to the touch input device, only one of the first and second insulation layers 470 and 471, which is farther from the reference potential layer 600 than the other, may include the support layers 470b and 471b.
Likewise, as shown in (d) of
As shown in
Preferably, only one of the first and second insulation layers 470 and 471 may include the support layers 470b and 471b. Specifically, in the state where the pressure sensor 440 is attached to the touch input device, only one of the first and second insulation layers 470 and 471, which is farther from the side to which the pressure sensor 440 has been attached than the other, may include the support layers 470b and 471b.
The pressure sensor 440 shown in
A space in which the pressure sensor 440 is disposed, for example, an interval between the display module 200 and the substrate 300 depends on the touch input device and is about 100 to 500 μm. The thicknesses of the pressure sensor 440 and the support layers 470b and 471b are limited according to the interval. As shown in
The pressure sensor 440 is disposed in the touch input device. Therefore, as with the touch input device, the pressure sensor 440 is required to meet a given reliability under a predetermined condition, for example, temperature, humidity, etc. In order to meet the reliability that the appearance and characteristics are less changed under a harsh condition of 85 to −40° C., a humidity condition of 85%, etc., it is desirable that the support layers 470b and 471b are made of a resin material. Specifically, the support layers 470b and 471b may be formed of polyimide (PI) or polyethylene terephthalate (PET). Also, polyethylene terephthalate costs less than polyimide. The material constituting the support layers 470b and 471b may be determined in terms of cost and reliability.
As described above, in order to detect the pressure through the touch input device 1000 to which the pressure sensor 440 is applied according to the embodiment of the present invention, it is necessary to sense the capacitance change occurring in the pressure electrodes 450 and 460. Therefore, it is necessary for the driving signal to be applied to the drive electrode out of the first and second electrodes 450 and 460, and it is required to detect the touch pressure by the capacitance change amount by obtaining the sensing signal from the receiving electrode. According to the embodiment, it is possible to additionally include a pressure detection device in the form of a pressure sensing IC for the operation of the pressure detection. The pressure detection module (not shown) according to the embodiment of the present invention may include not only the pressure sensor 440 for pressure detection but also the pressure detection device.
In this case, the touch input device repeatedly has a configuration similar to the configuration of
According to the embodiment, the touch detection device 1000 may apply the driving signal for pressure detection to the pressure sensor 440 by using the touch detection device for the operation of the touch sensor panel 100, and may detect the touch pressure by receiving the sensing signal from the pressure sensor 440. Hereafter, the following description will be provided by assuming that the first electrode 450 is the drive electrode and the second electrode 460 is the receiving electrode.
For this, in the touch input device 1000 to which the pressure sensor 440 is applied according to the embodiment of the present invention, the driving signal may be applied to the first electrode 450 from the drive unit 120, and the second electrode 460 may transmit the sensing signal to the sensing unit 110. The controller 130 may perform the scanning of the touch sensor panel 100, and simultaneously perform the scanning of the touch pressure detection, or the controller 130 performs the time-sharing, and then may generate a control signal such that the scanning of the touch sensor panel 100 is performed in a first time interval and the scanning of the pressure detection is performed in a second time interval different from the first time interval.
Therefore, in the embodiment of the present invention, the first electrode 450 and the second electrode 460 should be electrically connected to the drive unit 120 and/or the sensing unit 110. Here, it is common that the touch detection device for the touch sensor panel 100 corresponds to the touch sensing IC 150 and is formed on one end of the touch sensor panel 100 or on the same plane with the touch sensor panel 100. The pressure electrode 450 and 460 included in the pressure sensor 440 may be electrically connected to the touch detection device of the touch sensor panel 100 by any method. For example, the pressure electrode 450 and 460 may be connected to the touch detection device through a connector by using the second PCB 210 included in the display module 200. For example, conductive traces 461 which electrically extend from the first electrode 450 and the second electrode 460 respectively may be electrically connected to the touch sensing IC 150 through the second PCB 210, etc.
Here, while
The connection method of
The foregoing has described the pressure electrodes 450 and 460, that is to say, has described that the first electrode 450 constitutes one channel as the drive electrode and the second electrode 460 constitutes one channel as the receiving electrode. However, this is just an example. According to the embodiment, the drive electrode and the receiving electrode constitute a plurality of channels respectively. Here, a high-pressure detection accuracy of the touch can be obtained by the plurality of channels constituted by the drive electrode and the receiving electrode, and it is possible to detect multi pressure of a multi touch.
As shown in
Here, described is a case in which the plurality of channels shown in
In the foregoing description, the first connector 121 or the fourth connector 474 may be a double conductive tape. Specifically, since the first connector 121 or the fourth connector 474 may be disposed at a very small interval, the thickness can be effectively reduced by using the double conductive tape rather than a separate connector. Also, according to the embodiment, the functions of the first connector 121 and the fourth connector 474 can be implemented by a Flex-on-Flex Bonding (FOF) method capable of achieving a small thickness.
Hereinafter, various methods in which the pressure sensor 440 detects the magnitude of the pressure of the touch on the basis of the capacitance change amount detected from the channel.
When a pressure is applied to the touch surface (S10), the magnitude of the touch pressure is detected based on the sum of the change amounts of the capacitances detected in the respective channels (S20). For example, the magnitude of the touch pressure can be calculated based on the sum of the change amounts of the capacitances detected in the respective fifteen first electrodes 450 in the pressure sensor 440 shown in
When the touch pressure is applied to the touch surface corresponding to a position “A” shown in
When a pressure is applied to the touch surface (S100), the magnitude of the touch pressure is detected based on the sum of values obtained by multiplying the change amount of the capacitance detected in each of the channels by a scaling factor assigned previously to each of the channels (S200). For example, as shown in
When the same touch pressure is applied, a volume (hereinafter, referred to as volume change amount) at which the touch input device 1000 is deformed when the touch pressure is applied to the central portion of the display module 200 may be greater than the volume change amount of the touch input device 1000 when the touch pressure is applied to the edge of the display module 200. In other words, when the same touch pressure is applied to the touch surface corresponding to the positions “A”, “B”, and “C” shown in
Here, when the touch pressure is applied to the same position, the magnitude of the applied pressure and the volume change amount of the touch input device 1000 have a linear relationship. In other words, when the touch pressures having different magnitudes are applied to any one of the positions “A”, “B”, and “C” shown in
Therefore, the magnitude of the pressure can be detected by estimating the volume change amount of the touch input device 1000.
First, when a pressure having a predetermined magnitude is applied to a predetermined touch position of the display module 200, a reference value corresponding to the touch position is stored in a memory (not shown) on the basis of the capacitance detected from each channel. In this case, the reference value may be the volume change amount of the touch input device 1000 calculated based on the capacitance detected from each channel. Alternatively, the reference value may be a normalized pressure value having a linear relationship with the volume change amount of the touch input device 1000, or may be a slope in the graph shown in
Next, a method for detecting the magnitude of the touch pressure by using the reference value is shown.
When a pressure is applied to the touch surface (S1000), the touch position is detected (S2000), and a distance change corresponding to each channel is calculated from the change amount of the capacitance detected in each channel (S3000).
The value of capacitance detected in each channel depends on the configuration of the pressure electrode or the configuration of the circuit for sensing the touch pressure. However, when the touch pressure is applied, the value of capacitance can be represented by a function of the distance change “di” corresponding to each channel shown in
Here, among the capacitance between the first electrode 450 and the second electrode 460, the capacitance which is lost as a reference potential layer is fringing capacitance. Here, the pressure capacitance 11 can be expressed as follows.
Cp=C0+Cfringing=C0+αf(d) Equation (2)
Here, Co is a fixed capacitance value generated between the first electrode 450 and the second electrode 460, and Cfringing is a capacitance value generated by fringing effect between the first electrode 450 and the second electrode 460. The equation (2) represents the value of Cfringing by the distance “d” and a coefficient “α”. The fixed capacitance means a capacitance generated by the first electrode 450 and the second electrode 460 irrespective of the distance “d” between the reference potential layer and the electrode.
When a random pressure is applied to any position of the display module 200, the distance change “di” corresponding to each channel can be calculated by performing an inverse calculation on the capacitance change amounts detected in each of the channels, the equation (1), and the equation (2).
When a first switch 21 is turned on, a capacitor for sensing the pressure capacitance 11 is charged to a power supply voltage VDD to which one end of the first switch 21 is connected. When a third switch 23 is turned on immediately after the first switch 21 is turned off, the electric charges charged in the capacitor for sensing the pressure capacitance 11 are transferred to an amplifier 31 to obtain the output signal Vo corresponding thereto. When a second switch 22 is turned on, all the electric charges remaining in the capacitor for sensing the pressure capacitance 11 are discharged. When the third switch 23 is turned on immediately after the second switch 22 is turned off, the electric charges are transferred to the capacitor for sensing the pressure capacitance 11 through a feedback capacitor 32 to obtain the output signal corresponding thereto. Here, the output signal Vo of the circuit shown in
Here, ε is a dielectric constant εoεr of the material filled between the first electrode 450 and the reference potential layer, and “A” is the area of the first electrode 450.
When a random pressure is applied to any position of the display module 200, the distance change “di” corresponding to each channel can be calculated by performing an inverse calculation on the capacitance change amounts detected in each of the channels and the equation (3).
The volume change amount of the touch input device is estimated by using the calculated distance change “di” corresponding to each channel (S4000). Specifically, when the touch pressure is applied, the surface of the touch input device 1000 is deformed as shown in
Here, when the touch pressure is applied to a predetermined position, the magnitude of the applied pressure and the volume change amount of the touch input device 1000 have, as shown in
For example, when the estimated volume change amount of the touch input device 1000 is 1000 and the volume change amount stored in the memory as a reference value corresponding to the touch position for a pressure of 800 g is 2000, the magnitude of the applied pressure is 400 g.
Also, when the reference value corresponding to the input touch position is not stored in the memory, the pressure value can be calculated through various interpolations such as linear interpolation, bi-cubic interpolation, etc., by using the reference value which is stored in the memory and corresponds to a touch position adjacent to the input touch position.
For example, when reference values corresponding to the position “A” and the position “B” shown in
The foregoing has described that the third method for detecting the touch pressure by using the plurality of channels. However, as shown in
When a pressure is applied to the touch surface, the touch position is detected, and the distance change can be calculated from the change amount of the capacitance detected in the single channel.
The value of the capacitance detected in the single channel can be represented by a function of the distance change corresponding to the single channel. Therefore, the distance change corresponding to the single channel can be calculated by performing an inverse calculation on the capacitance value detected from the single channel.
When a random pressure is applied to any position of the display module 200, the distance change corresponding to the single channel can be calculated by performing an inverse calculation on the capacitance change amount detected in the single channel and the equations (1), (2) or (3).
The volume change amount of the touch input device is estimated by using the calculated distance change corresponding to the single channel. Specifically, when the touch pressure is applied, the volume change amount of the touch input device may be a value obtained by multiplying the distance change corresponding to the single channel by the areas of the single electrodes 450 and 460.
Here, when the touch pressure is applied to a predetermined position, the magnitude of the applied pressure and the volume change amount of the touch input device 1000 have, as shown in
As described above, by calculating the magnitude of the pressure on the basis of the volume change amount by the touch pressure, it is possible to detect a more accurate pressure magnitude. The accurate magnitude of the pressure can be detected even though the reference potential layer or the pressure sensor is deformed from its initial position.
Although the pressure sensor 440 having the type shown in
When the pressure sensor 440 is configured to form a plurality of channels, multi pressure of a multi touch can be detected. This can be performed, for example, by using the pressure magnitudes obtained from the channels of the pressure electrodes 450 and 460 disposed at a position corresponding to each of the multiple touch positions obtained from the touch sensor panel 100. Alternatively, when the pressure sensor 440 is configured to form a plurality of channels, the touch position can be directly detected by the pressure sensor 440, and multi pressure can be also detected by using the pressure magnitudes obtained from the channels of the pressure electrodes 450 and 460 disposed at the corresponding position.
Although embodiments of the present invention were described above, these are just examples and do not limit the present invention. Further, the present invention may be changed and modified in various ways, without departing from the essential features of the present invention, by those skilled in the art. For example, the components described in detail in the embodiments of the present invention may be modified. Further, differences due to the modification and application should be construed as being included in the scope and spirit of the present invention, which is described in the accompanying claims.
REFERENCE NUMERALS
1000: touch input device
100: touch sensor panel
120: drive unit
110: sensing unit
130: controller
200: display module
300: substrate
420: spacer layer
440: pressure sensor
450, 460: pressure electrode
470: first insulation layer
471: second insulation layer
470a, 471a: electrode covering layer
470b, 471b: support layer
430: adhesive layer
435: protective layer
480: elastic layer
Yoon, Sang Sic, Seo, Bong Jin, Jun, Jae Bum, Lee, Hwan Hee, Kim, Bon Kee, Jin, Myung Jun
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